WO2022100942A1 - Device and method for transferring a catalyst-coated membrane or a gas diffusion layer - Google Patents

Abstract

The invention relates to a device and to a method for transferring a functional layer, in particular a catalyst-coated membrane (2) and/or a gas diffusion layer for a membrane electrode assembly, onto a first material web, wherein: precuts (20) of a functional layer are transferred onto a moving counter surface with a first spacing (x1); the precuts (20) are supplied by means of a second material web (3) with a second spacing; the first spacing (x1) is greater than the second spacing (x2); the second material web (5), at least in a handover portion for carrying over a precut (20) moves synchronously with a conveying speed of the counter surface and is braked relative to the conveying speed to change the spacing; and the dispensing edge (6) in the first transport direction (I) relative to the second material web (5) is adjusted in order to create a braking and acceleration section for the precuts (20) moving discontinuously with the second material web (5).

Description

DEVICE AND METHOD FOR TRANSMITTING A

CATALYST COATED MEMBRANE OR A GAS DIFFUSION LAYER

FIELD OF APPLICATION AND PRIOR ART

The invention relates to a device and a method for transferring a functional layer onto a moving first web of material, in particular for transferring a catalyst-coated membrane and/or a gas diffusion layer for a membrane electrode arrangement.

Membrane electrode assemblies (MEA for short) for fuel cells comprising a catalyst-coated membrane (CCM for short for “catalyst coated membrane”) and two electrodes designed as cathode and anode, between which the membrane is arranged, are well known . An MEA also includes two gas diffusion layers (GDL for short), which are arranged on the sides of the electrodes facing away from the membrane. In one embodiment, the GDL and the electrodes are formed as a single structure. A fuel cell can be constructed from a large number of membrane electrode arrangements arranged in a stack, the electrical power of which is added up.

A gas diffusion layer, a gas diffusion layer in combination with an electrode, a catalyst layer, a membrane, a catalyst-coated membrane or a catalyst-coated membrane in combination with a polymer film are referred to collectively as a functional layer in connection with the application.

DE 102015 010440 A1 discloses a method for producing a

Membrane electrode arrangement for a fuel cell is known, in which at least one frame material is provided as a continuous web of material, which is continuously moved in the direction of transport and thereby runs through a plurality of processing stations, the membrane, the anode and the cathode being connected to the frame material in respective processing stations. In one configuration, the membrane is provided as a blank. In other configurations, the membrane is provided as a web of material, with a blank of the membrane being separated from the web of material at the associated processing station and connected to the frame material. TASK AND SOLUTION

It is an object of the invention to create a device and a method for transferring a functional layer, in particular a membrane and/or a gas diffusion layer, onto a moving web of material for the production of membrane electrode assemblies, which allows reliable handling of materials sensitive to tension, such as membranes or gas diffusion layers , and allow a precise transfer to the material web.

According to a first aspect, a device for transferring a functional layer to a moving first web of material, in particular for transferring a catalyst-coated membrane and/or a gas diffusion layer for a membrane electrode assembly of a fuel cell, is created, which is set up to cut the functional layer, in particular the membrane and/or the gas diffusion layer, at a first distance to a counter-surface moved at a conveying speed, the device having a feed device for feeding the blanks on a second web of material and a dispenser edge extending transversely to the direction of the second web of material, around which the second Material web for detaching the blanks is guided with a change of direction from a first transport direction into a second transport direction, wherein the blanks are arranged on the second material web with a second spacing, the first spacing is greater than the second distance, the feed device being suitable for moving the second material web at least in a transfer section for a transfer of a blank synchronously with the conveying speed, and for decelerating the second material web at least in the transfer section for a distance change relative to the conveying speed , and wherein the dispenser edge is mounted adjustably in the first transport direction relative to the second web of material and can be adjusted by means of an adjusting device in order to create a braking and acceleration section for the blanks that are moved discontinuously with the second web of material.

The terms "a", "an" etc. are used in connection with the application only as indefinite articles and not as measure words. The terms "first", "second", etc. are used only to distinguish between elements and do not indicate a hierarchy of elements.

The counter-surface can be the first web of material or a surface of an intermediate device, for example a roller. The counter surface is moved at a conveying speed. In advantageous configurations, a continuous movement of the opposing surface is provided. In connection with the application, a continuous movement is a movement in which a conveying speed is constant or at least almost constant during a transfer cycle, ie from the start of the transfer of a blank to the start of the transfer of a subsequent blank. In one embodiment, the conveying speed is gradually increased or decreased over a transmission cycle.

The second web of material is moved discontinuously relative to the conveying speed. A movement that is discontinuous relative to the conveying speed is a movement in which a transport speed of the material web is not continuously synchronous with the conveying speed. For a tension-free transfer of the blanks, the second material web is moved during the transfer at a first transport speed, which is synchronous with the conveying speed of the opposite surface, for example the first material web. To increase the distance, the second web of material stands still or is decelerated to a lower transport speed. In advantageous configurations, a transfer takes place only when the blanks are moved synchronously with the conveying speed,

In one embodiment, the first material web is a frame material web as described in DE 10 2015 010 440 A1. In other configurations, the web of material is a carrier web which is only used to transport components of a membrane electrode arrangement, but is separated from the membrane electrode arrangement before or when it is completed. In one embodiment, further components of the membrane electrode arrangement are already provided on the first web of material, in particular anode or cathode blanks are already provided on the first web of material in one embodiment, with the blanks of the functional layer, in particular the membrane, being precisely positioned on them and connected to them be able.

The blanks of the functional layer, in particular the membrane and/or the gas diffusion layer, are produced in one embodiment by kiss-cutting, the functional layer, in particular the membrane and/or the gas diffusion layer, being laminated with the second web of material is provided and fed to a cutting device. In one embodiment, residues of the functional layer remain on the second web of material after the blanks have been detached. A section in which the blanks are transferred to the opposite surface and/or are made available for a subsequent transfer is referred to as a transfer section.

A dispenser edge extending transversely to the direction of the second material web is provided for reliable detachment of the blanks from the second material web, around which the second material web is guided to detach the blanks, changing direction from a first transport direction to a second transport direction. In the context of the application, a dispenser edge is an edge that is used both for detaching and for transferring the blank to the opposite surface. Depending on the application, the dispenser edge can be suitably designed by the person skilled in the art, in particular also in order to separate residual parts of the functional layer, in particular the membrane and/or the gas diffusion layer, which are to remain on the second web of material, from the blanks to be transferred. In one embodiment, the dispenser edge is at least partially made of an elastic material in order to compensate for any unevenness in the opposing surface.

The dispenser edge is mounted so that it can be adjusted in the first transport direction relative to the second web of material and can be moved by means of an adjusting device in order to create a braking and acceleration section for the blanks that are moved discontinuously with the second web of material.

The adjustment movement makes it possible for the blanks to be moved exclusively synchronously with the conveying speed of the opposite surface during the transfer by means of the second web of material. Due to the movement of the dispenser edge relative to the second web of material, a movement of the blanks over the dispenser edge and a resulting detachment of the blanks from the second web of material during deceleration and/or acceleration, i.e. as long as the second web of material is not yet or no longer a for having the transport speed required for the transfer is prevented. This can prevent a front end of the blanks from being exposed, i.e. being supported neither by the second web of material nor by the counter-surface. This is particularly advantageous for processing a catalyst-coated membrane for a membrane electrode arrangement, which usually has a low inherent rigidity.

The adjusting device is preferably also suitable for moving the dispenser edge relative to the first web of material or an alternative counter-surface in the direction of or away from the counter-surface in order to apply a pressing force to the blank during a transfer cause and to avoid contact of the blanks or the second web of material with the counter-surface without transfer of a blank. In connection with the application, a movement which has at least one essential component in the first transport direction is referred to as a movement of the dispenser edge in the first transport direction. Due to a movement of the dispenser edge relative to the counter surface, the first transport direction is not constant. In the case of a transfer, the second web of material is transported at an acute angle to the opposite surface or at a tangent to the opposite surface. During a standstill, the first transport direction can essentially run parallel to the transport direction of the counter surface or a tangent to the counter surface.

In one embodiment, a sensor device is provided in order to detect a position of a front end of a blank to be subsequently transferred, and to control or regulate the actuating device and/or a transport speed of the second web of material accordingly. In one embodiment, the sensor device comprises a sensor integrated into the dispenser edge or attached to the dispenser edge.

The device is suitable for moving the second web of material for a transfer of a blank synchronously with the conveying speed. In one configuration, the adjusting device for the dispenser edge is set up to adjust the dispenser edge backwards relative to the second material web in the first transport direction when a blank is transferred and to adjust the Dispenser edge to adjust relative to the second web of material in the first transport direction forward. Due to the forward adjustment movement of the dispenser edge in the first transport direction, a front end of a blank to be subsequently transferred to the counter surface is upstream of the dispenser edge before the second material web is accelerated to the transport speed of the counter surface. When the second web of material accelerates, the dispensing edge is kept stationary in advantageous configurations. The distance between the front end of the blank and the donor edge serves as an acceleration distance and is chosen so that when the desired transport speed is reached, the front end of the blank reaches an area adjacent to a front end of the donor edge, so that the donor edge starts the transfer of the blank, a pressing force can be applied to the blank. In order to also provide a corresponding acceleration section for a subsequent blank, the dispenser edge is adjusted backwards during the transfer of the blank. After a blank has been transferred, the second web of material is decelerated, with the donor edge being adjusted forwards in order to prevent the following blank from moving over the donor edge during the deceleration of the to avoid web of material. In one embodiment, while the second web of material is at a standstill, there is no adjustment movement of the dispenser edge. In other configurations, the dispensing edge is moved further forward while the second web of material is at a standstill in order to create a longer acceleration distance.

In order to avoid tensile stresses and/or stagnation points due to shortening or lengthening of a web path after the donor edge when the donor edge is offset, a discontinuously operable take-off unit is provided in one embodiment. However, such a withdrawal device requires a high level of control effort. In advantageous configurations, the second web of material is therefore guided downstream of the dispenser edge via a compensation device for length compensation when the dispenser edge moves. In one embodiment, the compensating device is positively controlled. A positively controlled compensating device is particularly advantageous when the acceleration and deceleration ramps of a movement profile of the donor edge are so strong that a passively guided cylinder cannot follow quickly enough due to its inertia, and without positive control there is a risk of web breaks or web tension losses occurring. In one embodiment, the compensating device comprises a pneumatically acted upon roller. This creates an inexpensive compensating device.

In one embodiment, the second material web is drawn off directly from a supply roll by means of a discontinuously operated roller and, after the blanks have been transferred, is wound up by means of a discontinuously operated roller. In other configurations, the second web of material is integrated into a continuous process. For example, it is conceivable that the punching described above takes place in a continuous process. In order to achieve a discontinuous movement in the transfer section of the second web of material, in one embodiment a dancer device is provided upstream and/or downstream of the transfer section. In one embodiment, at least one of the dancer devices is positively guided. The forced guidance or forced movement of the dancer device serves to avoid mass inertia effects and spring effects on the material web, which could lead to expansion fluctuations. In an advantageous embodiment, for the discontinuous movement of the second web of material in the transfer section, the second web of material is guided upstream and downstream of the transfer section via two positively guided dancer devices coupled to one another. The coupling uses the property that for a deceleration, if necessary to a standstill and an acceleration of the material web with the cut in front of the transfer point and the material web without the cut After the transfer point, length adjustments that are the same in terms of amount but are directed in opposite directions are necessary. Depending on the application, the coupling can be implemented mechanically or by means of control technology. It is apparent to the person skilled in the art that the design of the device with two dancer devices coupled to one another for a discontinuous movement of a material web along a transfer section not only in combination with a moving dispenser edge, but also in connection with alternative devices for transferring a discontinuously transported material to a continuously moving first material web is advantageous.

In one embodiment, the blanks are transferred from the second web of material to a transfer device comprising a roll or a plurality of rolls. In other configurations, the device is set up to transfer the blanks directly from the second web of material to the first web of material. In other words, the first web of material serves as a counter surface. In other words, a device is created for transferring a functional layer, in particular a catalyst-coated membrane and/or a gas diffusion layer for a membrane electrode arrangement, onto a first material web that is moved at a conveying speed, with the device being set up to cut the functional layer onto the first material web to transmit at a first distance.

According to a second aspect, a method for transferring a functional layer, in particular a catalyst-coated membrane and/or a gas diffusion layer for a membrane electrode assembly of a fuel cell, to a first web of material is created, wherein blanks of the functional layer are placed on a counter surface moved at a conveying speed with a first Distance are transferred, the blanks being fed by means of a second material web at a second distance, the first distance being greater than the second distance, the second material web for detaching the blanks around a dispenser edge extending transversely to the direction of the second material web, with a change of direction is guided from a first transport direction into a second transport direction, the second material web being moved synchronously to the conveying speed at least in a transfer section for a transfer of a blank and for a distance change g is decelerated relative to the conveying speed, and wherein the dispenser edge is adjusted in the first transport direction relative to the second web of material in order to create a braking and acceleration distance for the blanks that are moved discontinuously with the second web of material. Due to the discontinuous movement of the second web of material relative to the conveying speed, it is possible to feed the blanks by means of the second web of material without the blanks having the same spacing on the second web of material as on the first web of material. In one configuration, when a blank is transferred at the conveying speed, the donor edge is moved backwards relative to the second material web in the first transport direction, and when the second material web is braked and/or when the second material web is at a standstill, the donor edge is moved relative to the second material web in adjusted to the front in the first transport direction.

In an advantageous embodiment, the second web of material is guided downstream of the dispenser edge via a compensation device for length compensation when the dispenser edge moves.

In one embodiment, it is further provided that for the discontinuous movement of the second web of material in the transfer section, the second web of material is guided upstream and downstream of the transfer section via two dancer devices coupled to one another.

In one embodiment, the blanks are transferred to the first web of material indirectly, by means of a transfer device provided between the first and second web of material. In advantageous configurations, the blanks are transferred directly from the second web of material to the first web of material, with the first web of material serving as a counter surface. In other words, a method for transferring a functional layer, in particular a catalyst-coated membrane and/or a gas diffusion layer for a membrane electrode arrangement, to a first material web that is moving at a conveying speed is created, with blanks of the functional layer being transferred to the moving first material web at a first distance will.

BRIEF DESCRIPTION OF THE DRAWINGS

Further advantages and aspects of the invention result from the claims and from the description of exemplary embodiments of the invention, which are explained below with reference to the figures. show: 1: a first embodiment of a device for transferring a membrane to a continuously moving first web of material at the beginning of a transfer of a blank from a second web of material to the first web of material,

2: the device according to FIG. 1 during the transfer of the blank and movement of a donor edge,

3: the device according to FIG. 1 after completion of the transfer of the blank,

4: the device according to FIG. 1 after completion of the transfer of the blank and with a deceleration of the second web of material,

5 shows the device according to FIG. 1 after the transfer of the blank has been completed

standstill of the second material web,

6: the device according to FIG. 1 before the transfer of the blank, with an acceleration of the second web of material,

7: the device according to FIGS. 1 to 6 with two dancer devices for a discontinuous movement of the second material web 5,

8 shows a second embodiment of a device for transferring a membrane onto a continuously moving first web of material, comprising a transfer device.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

1 to 6 show diagrammatically a first embodiment of a device 1 for transferring a membrane 2 to a continuously moving first web of material 3.

The membrane 2 is, for example, a catalyst-coated membrane for a membrane electrode arrangement (not shown) of a fuel cell (not shown). In an alternative embodiment, instead of a membrane 2 , a gas diffusion layer or another functional layer is transferred to the continuously moving first material web 3 by means of the device 1 . The membrane 2 and/or an alternative functional layer is provided in the form of blanks 20 and transferred to the first material web 3 at a transfer point 4 with a first distance x1. In one embodiment, the first web of material 3 is a transport web on which components of the membrane electrode arrangement are stacked and connected to one another.

In the embodiment shown in FIGS. 1 to 6, the blanks 20 of the membrane 2 are placed directly on the first web of material 3, i.e. the first web of material 3 serves as counter surfaces for a transfer.

A second web of material 5 is provided for providing the blanks 20 of the membrane 2, the blanks 20 being arranged on the second web of material with a second spacing x2. The blanks 20 are formed, for example, by means of die-cutting a laminate comprising the second web of material 5 and the membrane 2 . The second distance x2 is smaller than the first distance x1. In one configuration, the second distance x2 is almost zero and corresponds only to a width of a cutting edge, by means of which the blanks 20 are formed.

The device 1 shown in Figs. 1 to 6 comprises a dispensing edge 6 extending transversely to the direction of the second material web 5, around which the second material web 5 is guided with a change of direction from a first transport direction I to a second transport direction II for detaching the blanks 20 is.

The dispensing edge 6 is mounted so that it can be adjusted in the first transport direction I relative to the second material web 5 and can be adjusted by means of an adjusting device 60 shown schematically.

For length compensation when the donor edge 6 moves, the second web of material 5 is guided downstream of the donor edge 6 via a compensation device 7 comprising a roller 70 pneumatically acted upon by a pressure cylinder 71 .

Upstream of the dispensing edge 6, the second material web 5 is guided over two driven rollers 50 in the exemplary embodiment shown. Downstream of the dispenser edge 6, the second material web 5 is guided over a roller 51, the roller 70 of the compensating device 7 and a driven roller 52 in the exemplary embodiment shown. The first material web 3 is moved at a conveying speed. To change the distance x1, x2 between the blanks 20 during a transfer to the first material web 3, the second material web 5 is moved discontinuously relative to the conveying speed, at least in a transfer section shown in FIGS.

For a tension-free transfer of the blanks 20, the second material web 5 is moved during a transfer shown in FIGS. 1 and 2 to the first material web 3 synchronously with the conveying speed of the first material web 3 along the transfer section shown. To increase the distance, the second web of material 5 is stopped in the exemplary embodiment shown. The first web of material 3 is then moved on at the conveying speed, as shown schematically in FIG.

To stop the second web of material 5, it is braked, as shown in FIG. 4, until the second web of material 5 comes to a standstill. In order to bring the second web of material 5 from a standstill back to the transport speed that is synchronous with the conveying speed, the second web of material 5 is accelerated, as shown in FIG.

The second web of material 5 is decelerated and accelerated without a blank 20 being transferred from the second web of material 5 to the first web of material 3. For this purpose, the dispensing edge 6 is lifted from the first web of material 3, as shown in FIGS.

In order to prevent the second web of material 5 from moving over the dispenser edge 6 when braking or accelerating, and thus preventing a blank 20 from detaching from the web of material 5 and an exposed section of the blank 20, the dispenser edge 6 is adjusted relative to the second web of material 5 so that a Braking and acceleration section for the discontinuously moved with the second material web 5 blanks 20 is created.

As shown in Figs. 5 and 6, to create an acceleration section, the dispenser edge 6 is adjusted forwards in the transport direction I in such a way that a front end 61 of the dispenser edge 6 in the first transport direction I downstream of a front end 200 after the conveying speed has been reached transmitting blank 20 is located. When the material web 5 is accelerated to the conveying speed, this blank 20 is moved in the direction of the front end 61 of the dispenser edge 6 . The offset of the donor edge 6 is chosen such that the material web 5 reaches the transport speed desired for a tension-free transfer when or before the front end 200 of the blank 20 reaches the front end 61 of the donor edge 6 . For a transfer of the blank 20 with With a transport speed that is synchronous with the conveying speed, the dispenser edge 6 in the exemplary embodiment shown moves in the direction of the first material path

3 lowered, as shown in Fig. 1.

In order to be able to move the donor edge 6 forward again in the transport direction for a subsequent blank 20, when the blank 20 is transferred, the donor edge 6 is moved backwards relative to the second material web 5 in the first transport direction I, as shown in Figs 3 shown. In this case, the roller 70 of the compensating device 7 is adjusted to the right in the plane of the drawing for a length compensation downstream of the transfer point 4 . After the blank 20 has been transferred, the donor edge 6 is lifted from the first material web 3 and the second material web 5 is decelerated until it comes to a standstill. In order to prevent the following blank 20 from moving over the donor edge 6 when braking, the donor edge 6 is adjusted forwards in the first transport direction I relative to the second material web 5 . In this case, the roller 70 of the compensating device 7 is adjusted to the left in the plane of the drawing for length compensation downstream of the transfer point 4 .

In one embodiment, an adjustment movement of the donor edge 6 relative to the second web of material 5 when braking the second web of material 5 is sufficient to create an acceleration distance, so that while the second web of material 5 is stationary, the donor edge 6 is also held in position. In another embodiment, the dispensing edge 6 is moved further forward while the second web of material 5 is stationary.

The driven rollers 50, 52 are operated in a synchronized manner for reliable transport of the second material web 5. In one embodiment, the rollers 50 also serve as a take-off for the discontinuous unwinding of the material web 5 from a supply (not shown).

In an alternative embodiment, dancer devices 8 are provided upstream and downstream of the transfer area shown in FIGS.

FIG. 7 shows the device 1 according to FIGS. 1 to 6, the second web of material being guided upstream and downstream of the transfer section via two positively guided dancer devices 8 coupled to one another. Upstream and downstream of the transfer section, the second material web 5 is transported continuously at a constant transport speed, the transport speed being lower than the transport speed of the first material web 3. The coupling of the dancer devices 8 is implemented mechanically in the embodiment shown. In other configurations, a control-related coupling is provided.

The coupling of the dancer devices 8 uses the property that a length compensation for braking, if necessary, to a standstill, as well as an acceleration of the second material web 5 and a movement synchronous to the conveying speed of the first material web 3 before the transfer section, is equal in amount to a length compensation for braking, if necessary .is synchronous to the conveying speed of the first material web 3 after the transfer section up to a standstill and an acceleration and a movement. During braking and when stationary, the dancer device 8 arranged upstream of the transfer section temporarily stores a section of the material web 5, while the dancer device 8 arranged downstream of the transfer section releases a stored section of the material web 5. Conversely, when accelerating and moving at the transport speed of the first material web 3, the dancer device 8 arranged upstream of the transfer section releases a temporarily stored section of the material web 5, while the dancer device 8 arranged downstream of the transfer section temporarily stores a section of the material web 5.

Fig. 8 shows a second embodiment of a device 1 for transferring a membrane 2 and/or another functional layer onto a first material web 3 moving at a conveying speed. The device 1 shown in Fig. 8 essentially corresponds to the device 1 according to Fig. 7 and uniform reference numbers are used for identical components. In contrast to the device according to Fig. 7, the device 1 shown in Fig. 8 also includes a transfer device 9 with a roller 91. The roller 91 is in contact with the first web of material 3 coordinated rotational speed for a tension-free transfer of the blanks 20 from the roller 91 to the first material web 3 operated.

Blanks 20 of the membrane 2 are provided by the second web of material 5 at a distance x2 and are transferred from the second web of material 5 to the roller 91 . One surface of the roller 91 thus serves as a counter surface for the transfer.

In order to increase the distance between the blanks 20, the second web of material 5 is moved discontinuously in a transfer section, as described above, relative to the conveying speed. For the discontinuous movement of the second web of material 5, the second web of material 5 is guided upstream and downstream of the transfer section, analogously to FIG. Upstream and downstream of the transfer section, the second material web 5 is transported at a preferably constant conveying speed, the conveying speed being lower than the conveying speed of the first material web 3. In the exemplary embodiment, the dancer devices 8 each comprise a pressure-loaded roller 80, which moves the material web 5 discontinuously moving section contacted. However, the illustration of the dancer devices 8 in FIGS. 7 and 8 is only schematic and can be suitably implemented by a person skilled in the art depending on the application.

The configurations described above are merely exemplary and numerous modifications are conceivable.

Claims

Device for transferring a functional layer, in particular a catalyst-coated membrane (2) and/or a gas diffusion layer for a membrane electrode arrangement, onto a moving first web of material (3), the device being set up to transfer blanks (20) of the functional layer onto a counter-surface moving at a conveying speed at a first distance (x1), characterized in that the device has a feed device for feeding the blanks (20) on a second web of material (5) and one extending transversely to the direction of the second web of material (5). Dispenser edge (6), around which the second web of material (5) is guided for detaching the blanks (20) with a change of direction from a first transport direction (I) to a second transport direction (II), the blanks (20) on the second Material web (5) are arranged at a second distance (x2), the first distance (x1) being greater than al s is the second distance (x2), the feed device being suitable for moving the second material web (5) synchronously with the conveying speed, at least in a transfer section for transferring a blank (20), and for moving the second material web (5) at least in to brake the transfer section for a change in distance relative to the conveying speed, and wherein the dispensing edge (6) is mounted adjustably in the first transport direction (I) relative to the second material web (5) and is adjustable by means of an adjusting device (60) in order to and creating an acceleration path for the blanks (20) moved discontinuously with the second web of material (5). Device according to Claim 1, characterized in that the adjusting device (60) is set up to move the dispenser edge (6) backwards and at a transfer of a blank (20) relative to the second material web (5) in the first transport direction (I). braking the second material web (5) and/or when the second material web (5) is at a standstill, to adjust the dispensing edge (6) forwards relative to the second material web (5) in the first transport direction (I). Device according to Claim 1 or 2, characterized in that the adjusting device (60) is set up in order to move the dispensing edge (6) relative to the counter-surface towards or away from the counter-surface in order to exert a pressing force on the blank (20) in the event of a transfer and in order to avoid contact of the blanks (20) or the second material web (5) with the counter-surface without a blank (20) being transferred. Device according to Claim 1, 2 or 3, characterized in that the second material web (5) is guided downstream of the dispenser edge (6) via a compensation device (7) for length compensation when the dispenser edge (6) moves. Device according to one of Claims 1 to 4, characterized in that for the discontinuous movement of the second material web (5) in the transfer section, the second material web (5) is guided upstream and/or downstream of the transfer section via a positively guided dancer device (8), wherein the second material web (5) is guided in particular upstream and downstream of the transfer section via two positively guided dancer devices (8) coupled to one another. Device according to one of Claims 1 to 5, characterized in that the device is set up to transfer the blanks (20) directly from the second web of material (5) to the first web of material (3). Method for transferring a functional layer, in particular a catalyst-coated membrane (2) and/or a gas diffusion layer for a membrane electrode arrangement, to a moving first web of material (3), wherein blanks (20) of the functional layer are placed on a counter surface moved at a conveying speed with a first distance (x1), characterized in that the blanks (20) are fed to the functional layer by means of a second material web (3) at a second distance (x2), the first distance (x1) being greater than the second distance ( x2), wherein the second material web (5) for detaching the blanks (20) around a dispenser edge (6) extending transversely to the direction of the second material web (5) with a change of direction from a first transport direction (I) to a second transport direction (II) is performed, wherein the second material web (5) synchronously z u of the conveying speed and is decelerated relative to the conveying speed for a distance change, and wherein the dispenser edge (6) is adjusted in the first transport direction (I) relative to the second material web (5) in order to create a deceleration and acceleration distance for the discontinuous with the second material web (5) to create moving blanks (20). The method according to claim 7, characterized in that when a blank (20) is transferred, the donor edge (6) relative to the second material web (5) in the first transport direction (I) backwards and when braking the second 17

Material web (5) and/or when the second material web (5) is at a standstill, the dispenser edge (6) is adjusted forwards relative to the second material web (5) in the first transport direction (I). Method according to Claim 7 or 8, characterized in that the dispenser edge (6) is moved relative to the counter-surface at the beginning of the transfer in the direction of the counter-surface and after the transfer away from it in order to apply a pressing force on the blank (20) at which To effect transfer and to avoid contact of the blanks (20) or the second material web (5) with the counter-surface without transfer of a blank (20). Method according to Claim 7, 8 or 9, characterized in that the second material web (5) is guided downstream of the dispenser edge (6) via a compensation device (7) for length compensation when the dispenser edge (6) moves. Method according to one of Claims 7 to 10, characterized in that for the discontinuous movement of the second material web (5) in the transfer section, the second material web (5) is guided upstream and/or downstream of the transfer section via a forced dancer device (8), wherein in particular the second material web (5) is guided upstream and downstream of the transfer section via two positively guided dancer devices (8) coupled to one another. Method according to one of Claims 7 to 11, characterized in that the blanks (20) are cut directly from the second material web ( 5) are transferred to the first material web (3).